Coordinated Regulation of Heterochromatic Genes in<i>Drosophila melanogaster</i>Males

Deng, Xinxian; Koya, S. Kiran; Kong, Ying; Meller, Victoria H.

doi:10.1534/genetics.109.102087

Cited by 35 publications

(55 citation statements)

References 65 publications

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“…In principle, differences in the chromatin structure between males and females could result from various sources: The hemizygous X chromosome is dosage compensated in males, which is accomplished by changes in the chromatin structure (Straub and Becker 2007;Gelbart and Kuroda 2009); males contain a large heterochromatic Y chromosome that could alter the stoichiometric balance of heterochromatin/euchromatin between the sexes (Weiler and Wakimoto 1995;Deng et al 2009;Lemos et al 2010;; and many genes show sex-biased expression that could be associated with sex-specific chromatin modifications. Figure 3 shows a genome-wide karyotype view of the chromatin domains derived from female and male D. miranda larvae.…”

Section: Resultsmentioning

confidence: 99%

The chromatin landscape of Drosophila: comparisons between species, sexes, and chromosomes

Brown

Bachtrog

2014

Genome Res.

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The chromatin landscape is key for gene regulation, but little is known about how it differs between sexes or between species. Here, we study the sex-specific chromatin landscape of Drosophila miranda, a species with young sex chromosomes, and compare it with Drosophila melanogaster. We analyze six histone modifications in male and female larvae of D. miranda (H3K4me1, H3K4me3, H3K36me3, H4K16ac, H3K27me3, and H3K9me2), and define seven biologically meaningful chromatin states that show different enrichments for transcribed and silent genes, repetitive elements, housekeeping, and tissue-specific genes. The genome-wide distribution of both active and repressive chromatin states differs between males and females. In males, active chromatin is enriched on the X, relative to females, due to dosage compensation of the hemizygous X. Furthermore, a smaller fraction of the euchromatic portion of the genome is in a repressive chromatin state in males relative to females. However, sex-specific chromatin states appear not to explain sex-biased expression of genes. Overall, conservation of chromatin states between male and female D. miranda is comparable to conservation between D. miranda and D. melanogaster, which diverged >30 MY ago. Active chromatin states are more highly conserved across species, while heterochromatin shows very low levels of conservation. Divergence in chromatin profiles contributes to expression divergence between species, with~26% of genes in different chromatin states in the two species showing species-specific or species-biased expression, an enrichment of approximately threefold over null expectation. Our data suggest that heteromorphic sex chromosomes in males (that is, a hypertranscribed X and an inactivated Y) may contribute to global redistribution of active and repressive chromatin marks between chromosomes and sexes.

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Section: Resultsmentioning

confidence: 99%

The chromatin landscape of Drosophila: comparisons between species, sexes, and chromosomes

Brown

Bachtrog

2014

Genome Res.

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“…A prominent example is the global analysis of MOF, which revealed distinct binding behavior on the male X chromosome versus autosomal genes [20 ] (Figure 2). Furthermore, roX RNAs affect the regulation of genes on the fourth chromosome [47 ]. These studies raise the possibility of additional functions for these proteins/RNAs beyond dosage compensation.…”

Section: Role Of Msl Complex Members Beyond Dosage Compensationmentioning

confidence: 99%

The MSL complex: X chromosome and beyond

Laverty

Lucci

Akhtar

2010

Current Opinion in Genetics & Development

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“…One possible explanation for these observations is that global gene expression in Drosophila males is simply more sensitive than expression in females to genetic variation and divergence. For example, genetic perturbations affecting heterochromatin have more severe effects on genome-wide expression in males than females (Liu et al 2005;Deng et al 2009), which may reflect interactions with male-specific factors that affect both euchromatic and heterochromatic gene regulation, such as the Y chromosome (Lemos et al 2008b), or the somatic dosage compensation complex (Deng et al 2009). However, we caution that greater statistical power associated with the microarray experiments in males, e.g., due to greater technical variation or sensitivity to random environmental effects in females, could potentially contribute to the excess of divergently regulated genes detected in males.…”

Section: The Evolution Of Sexually Dimorphic Gene Expressionmentioning

confidence: 99%

The roles ofcis- andtrans-regulation in the evolution of regulatory incompatibilities and sexually dimorphic gene expression

et al. 2013

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Evolutionary changes in gene expression underlie many aspects of phenotypic diversity within and among species. Understanding the genetic basis for evolved changes in gene expression is therefore an important component of a comprehensive understanding of the genetic basis of phenotypic evolution. Using interspecific introgression hybrids, we examined the genetic basis for divergence in genome-wide patterns of gene expression between Drosophila simulans and Drosophila mauritiana. We find that cis-regulatory and trans-regulatory divergences differ significantly in patterns of genetic architecture and evolution. The effects of cis-regulatory divergence are approximately additive in heterozygotes, quantitatively different between males and females, and well predicted by expression differences between the two parental species. In contrast, the effects of trans-regulatory divergence are associated with largely dominant introgressed alleles, have similar effects in the two sexes, and generate expression levels in hybrids outside the range of expression in both parental species. Although the effects of introgressed trans-regulatory alleles are similar in males and females, expression levels of the genes they regulate are sexually dimorphic between the parental D. simulans and D. mauritiana strains, suggesting that purespecies genotypes carry unlinked modifier alleles that increase sexual dimorphism in expression. Our results suggest that independent effects of cis-regulatory substitutions in males and females may favor their role in the evolution of sexually dimorphic phenotypes, and that trans-regulatory divergence is an important source of regulatory incompatibilities.[Supplemental material is available for this article.] Phenotypic evolution occurs both by changes to RNA and protein sequences and by changes in the level at which these molecules are expressed within cells. Evolution of gene regulation was hypothesized (Britten and Davidson 1969;King and Wilson 1975) and has been demonstrated to constitute an important component of divergence among species and variation within populations, including significant contributions to human disease (Carroll 2005;Wray 2007;Fay and Wittkopp 2008;Romero et al. 2012). Broadly speaking, gene regulation requires the activity of trans-acting factors, which directly or indirectly regulate gene expression via RNA or protein intermediates, and cis-acting sequences, which modulate localization of trans-acting factors to DNA and their effects on the expression of nearby genes. Studies of the genetic control of gene expression indicate that there is abundant variation within natural populations in both cis-and trans-regulation and that both modes contribute to adaptation and divergence between species (Wray 2007;Fay and Wittkopp 2008). However, cis-and transregulation have been hypothesized to differ in important genetic and evolutionary properties. First, cis-regulatory variants have been observed to have quantitatively larger effects on expression than trans-regulatory variants (Brem et...

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Coordinated Regulation of Heterochromatic Genes inDrosophila melanogasterMales

Cited by 35 publications

References 65 publications

The chromatin landscape of Drosophila: comparisons between species, sexes, and chromosomes

The chromatin landscape of Drosophila: comparisons between species, sexes, and chromosomes

The MSL complex: X chromosome and beyond

The roles ofcis- andtrans-regulation in the evolution of regulatory incompatibilities and sexually dimorphic gene expression

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